KR102058524B1 - Air pump system and control method for beverage dispenser - Google Patents

Abstract

The present invention relates to an air pump system for a beverage extracting device and a control method, and specifically, to a system and a control method, which are possible to generate and control pressure for extracting beverages received in a beverage container by using air instead of carbon dioxide gas used in a conventional beverage extracting device. The control method includes: a step of driving an air pump injecting air through a flow path connected to a beverage container to generate extracting pressure for extracting beverages received in the beverage container; a step of measuring the extracting pressure or temperature near the air pump; and a step of controlling operation of the air pump so that the extracting pressure reaches target pressure based on the measured extracting pressure or the temperature.

Description

AIR PUMP SYSTEM AND CONTROL METHOD FOR BEVERAGE DISPENSER}

The present invention relates to an air pump system and a control method for a beverage extracting device, and specifically, to generate and adjust a pressure for extracting a beverage contained in a beverage container using air instead of carbon dioxide gas used in a conventional beverage extracting device. It relates to a system and a control method that can be.

Generally, an extraction apparatus for extracting known beverages, including draft beer, wine, coffee, and other drinking water, is used.

As shown in FIG. 1, the draft beer extraction device includes a beverage container containing draft beer, a carbon dioxide gas container containing CO ₂ for pushing the draft beer, a cooler for cooling the draft beer of the beverage container, and an ejector connected to the cooler. It includes.

That is, the conventional draft beer extraction apparatus follows a draft beer cooled by the draft beer cooler by using the pressure of CO ₂ contained in the carbon dioxide gas cylinder through the ejector of the draft beer cooler.

This draft beer extractor requires a separate carbon gas container for accommodating CO ₂ , and an empty carbon dioxide gas container is returned to the beer manufacturing plant to fill the CO ₂ after it is exhausted. Required.

This requires enormous costs and time in logistics, filling facilities, labor costs, and the like.

In addition, the beer extracted by the pressure and seasonal factors of the CO ₂ may occur a lot of foam, the problem of having to discard a certain amount at the beginning when replacing the beverage container and the carbon dioxide container.

In addition, after the CO ₂ is injected into the beverage container, if the draft beer is not extracted for a long time (about 1 month or more), the draft beer may be deteriorated.

An object of the present invention relates to a system and a control method capable of generating and regulating a pressure for extracting a beverage contained in a beverage container using air instead of carbon dioxide gas used in a conventional beverage extractor.

In order to achieve the above object, the present invention comprises the steps of driving an air pump for injecting air through a flow path connected to the beverage container to generate an extraction pressure for extracting the beverage contained in the beverage container; Measuring the extraction pressure or the temperature near the air pump; And adjusting the driving of the air pump so that the extraction pressure reaches the target pressure based on the measured extraction pressure or temperature.

The present invention comprises the steps of generating a position signal of the air pump; And determining whether the position of the air pump is included in a predetermined range based on the position signal.

The present invention comprises the steps of measuring the flow rate of air injected into the beverage container; Deriving an extraction amount of the beverage based on the flow rate; And calculating the total amount of the beverage by cumulatively calculating the extraction amount of the derived beverage for a predetermined period of time.

The present invention further includes the step of showing at least one of the extraction pressure, the target pressure, the temperature, the driving state and position of the air pump, and the total consumption of the beverage.

In order to achieve the above another object, the present invention provides an air pump for injecting air through a flow path connected to the beverage container to generate an extraction pressure for extracting the beverage contained in the beverage container; Sensor unit for measuring the extraction pressure or the temperature near the air pump; And a control unit for adjusting the driving of the air pump so that the extraction pressure reaches the target pressure based on the measured extraction pressure or temperature.

The air pump system and control method for a beverage extracting apparatus according to the present invention generates an extraction pressure using air instead of carbon dioxide gas through the air pump can be used to exclude the use of a conventional carbon dioxide gas cylinder.

In addition, it is possible to prevent the alteration of the beverage, including draft beer through the above-described effect.

In addition, the driving of the air pump may be automatically adjusted based on the extraction pressure generated by the air pump or the temperature near the air pump.

In addition, by detecting the position of the air pump, inventory management is easy and can reduce the possibility of theft and loss.

In addition, the extraction amount of the beverage can be checked in real time, and the total amount of the beverage can be easily identified for a certain period of time.

In addition, the target pressure can be set as desired by the user through the display unit or the user device, thereby making it easier to control the system.

1 is a conceptual diagram of a conventional draft beer extraction device.
Figure 2 is a block diagram of an air pump system for beverage extraction apparatus according to an embodiment of the present invention.
3A to 3C are front, plan and rear views of the air pump shown in FIG. 2 in sequence.
4 is a view showing the internal structure of the air pump shown in FIG.
5 is a conceptual diagram of the air pump shown in FIG. 2.
6 is a block diagram of the controller shown in FIG. 2.
FIG. 7 is a flowchart illustrating a control method of the air pump system for a beverage extraction device shown in FIG. 2.

DETAILED DESCRIPTION OF THE EMBODIMENTS In order to describe in detail such that those skilled in the art can easily implement the technical idea of the present invention, the most preferred embodiment of the present invention will be described with reference to the accompanying drawings.

First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used to refer to the same components even though they are shown in different drawings.

In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

1 to 6, it will be described with respect to the air pump system for beverage extraction apparatus according to an embodiment of the present invention.

1 is a conceptual diagram of a conventional draft beer extraction device.

Referring to FIG. 1, as described above, the draft beer extraction device includes a beverage container containing draft beer, a carbon dioxide gas container containing CO ₂ for pushing the draft beer, a cooler for cooling the draft beer of the beverage container, and an ejector connected to the cooler. .

Air pump system for beverage extraction apparatus according to an embodiment of the present invention to replace the carbon dioxide gas cylinder used in the extraction device for extracting known beverages, including draft beer, wine, coffee, other drinking water with an air pump for controlling It is to solve the above-mentioned problem including the additional configuration.

Figure 2 is a block diagram of an air pump system for beverage extraction apparatus according to an embodiment of the present invention.

Referring to FIG. 2, the beverage extraction apparatus air pump system 100 (hereinafter, referred to as a “system”) includes an air pump 110, a sensor unit 130, and a controller 120.

The air pump 110 injects air through the flow path 10 connected to the beverage container to generate an extraction pressure for extracting the beverage contained in the beverage container.

The sensor unit 130 detects an extraction pressure or a temperature near the air pump to derive a measurement value, and the controller 120 controls the air pump 110 to reach the target pressure based on the measurement value. Adjust the driving of

The sensor unit 130 measures the flow rate of air injected into the beverage container, and the control unit 120 calculates the total amount of the beverage used for a predetermined period of time based on the measured value.

3A to 3C are front views, top views, and rear views of the air pump shown in FIG. 2 in sequence, FIG. 4 is a diagram illustrating an internal structure of the air pump shown in FIG. 2, and FIG. 5 is shown in FIG. 2. Conceptual diagram of a conventional air pump.

3A to 5, the air pump 110 includes a motor pump 111 installed inside the case, and the flow path 10 connected between the motor pump 111 and the beverage container.

The flow path 10 includes an internal flow path 12 connected to the motor pump 111 and an external flow path 11 connected between the internal flow path 12 and the beverage container.

The inner passage 12 and the outer passage 11 are connected to each other via a connector 118 installed in the case.

The motor pump 111 comprises a pair of cylinders and a piston is installed therein, the motor 111a for driving the piston.

Here, the rotation of the motor 111a can be converted to linear movement through the cam structure.

The piston receives the rotational force of the motor 111a to reciprocate linearly move the inside of the cylinder to compress air and discharge the compressed air into the inner passage 12.

More specifically, the cylinder receives the compressed air from the first cylinder (111bb), the first cylinder 111bb and the first cylinder 111bb is carried out by the air inlet formed in the case is a secondary compression process This includes a second cylinder 111ba to be performed.

That is, by compressing the air compressed in the first cylinder (111bb) in the second cylinder (111ba), it is possible to increase the compression efficiency of the air.

The suction port may be provided with a dust filter 112, through which the foreign matter can be prevented from entering the inside of the case and the first cylinder (111bb) to ensure the integrity of the device, furthermore, the occurrence of failure You can prevent it.

The air pump 110 is provided with a pressure gauge 116 that displays the extraction pressure is formed through the motor pump 111.

In addition, the air pump 110 may include a cooling fan 113, and more specifically, the cooling fan 113 may be installed at a vent formed in the housing.

That is, the internal air of the case may be discharged to the outside through the cooling fan 113 to reduce heat generated by the driving of the motor pump 111.

The air pump 110 is provided with a power switch 119 for supplying power to the electronic device associated with the air pump 110, including the motor pump 111.

And the upper portion of the motor pump 111 is provided with a handle 117 for the user to easily carry the air pump 110.

Here, the pressure gauge 116, the cooling fan 113, the power switch 119, the handle 117 described above is not limited to the position shown in the drawing according to the manufacturing conditions, the arrangement conditions of the air pump 110 It can be installed in various locations.

The air pump 110 includes a valve unit 114 and a pressure switch 115.

More specifically, the valve unit 114 includes a check valve 114a, a solenoid valve 114b, a pressure regulating valve 114c, and the internal flow passage 12 sequentially based on the motor pump 111. It is installed on.

The check valve 114a is configured to prevent the air discharged from the second cylinder 111ba to the internal passage 12 back to the inside of the second cylinder 111ba.

When the extraction pressure reaches the target pressure through the motor pump 111, the driving of the motor pump 111 is stopped.

However, after reaching the target pressure, when the extraction pressure is lowered to restart the motor pump 111, a trip phenomenon occurs due to the internal pressure of the cylinder, and restarting is impossible.

To prevent this, by applying a current to the solenoid valve 114b before opening the motor pump 111, the tripping may be prevented by making the internal pressure of the cylinder parallel to the external pressure.

The pressure control valve 114c is configured to adjust the extraction pressure by the user to open and close arbitrarily, one side protrudes from the case so that the user can easily operate.

The pressure switch 115 is configured to drive or stop the driving of the motor pump 111. The pressure switch 115 is installed on the internal passage 12 so that when the extraction pressure reaches a target pressure, the motor pump 111 is disposed. When the driving of the motor is stopped and the target pressure is not reached, the motor pump 111 may be driven.

The sensor unit 130 includes a pressure sensor 131, a temperature sensor 132, and a flow sensor 133.

The pressure sensor 131 measures the extraction pressure generated through the motor pump 111 and is installed on the flow path 10.

The temperature sensor 132 measures the temperature of the space in which the beverage extraction device is installed, and is installed in the vicinity of the air pump 110.

The above-described temperature of the space may vary depending on the change of seasons or environmental conditions, and this may affect the pumping efficiency of the motor pump 111 and thus may be a factor of setting a target pressure.

Here, the installation position of the temperature sensor 132 is not limited to the vicinity of the air pump 110 can be expanded to the vicinity of the beverage extraction apparatus, including the air pump 110.

The flow rate sensor 133 measures the flow rate of air discharged from the motor pump 111 and injected into the beverage container, the branch flow path 13 is divided in the external passage 11 and connected to each beverage container Can be installed on each.

6 is a block diagram of the controller shown in FIG. 2.

Referring to FIG. 6, the control unit 120 includes an analysis unit 122, an adjusting unit 123, a warning unit 124, and a memory 121.

More specifically, the memory 121 is installed in a printed circuit board (PCB), the analysis unit 122, the adjusting unit 123, the warning unit 124 is a central processing unit is installed in a printed circuit board (PCB). Can be programmed to (CPU).

The memory 121 may store a condition value for controlling the driving of the air pump 110 including a target pressure.

For example, a target pressure may be generally set to 3 ~ 3.5bar, the motor pump 111 is driven when the measured value of the pressure sensor 131 is 3bar or less, and when the 3,5bar or more to stop the drive Can be set.

Here, the target pressure may be set arbitrarily by the user or may be set by reflecting the capacity difference of each model of the motor pump 111 or the type of beverage.

As another example, since the pumping efficiency of the motor pump 111 may vary according to the change of the surrounding temperature of the beverage extraction apparatus, the target pressure may be set for each neighboring temperature.

That is, when the measured value of the temperature sensor is less than 10 degrees, the predetermined target pressure may be set by lowering 30%, and the predetermined target pressure may be maintained at 10 to 30 degrees.

And, if it exceeds 30 degrees, the predetermined target pressure can be increased by 20% and set.

The analysis unit 122 extracts a corresponding target pressure stored in the memory 121 based on the measured value of the sensor unit 130.

Here, the sensor unit 130 may be electrically connected to the printed circuit board to transmit the measured value to the analysis unit 122, or wirelessly transmit the measured value through a communication unit to be described later.

The adjusting unit 123 transmits a driving signal or a stop signal of the motor pump 111 to the pressure switch 115 so that the extraction pressure reaches the target pressure extracted by the analyzing unit 122, and the pressure switch 115 controls the driving of the motor pump 111 by driving the motor pump 111 or stopping driving based thereon.

Here, before the extraction pressure is lowered to transmit the driving signal of the motor pump 111 to the pressure switch 115 to re-drive the motor pump 111, the analysis unit 122 is the motor pump ( 111 determines whether the target pressure has been performed before.

The controller 123 may generate a driving signal of the motor pump 111 based on the determination of the analyzer 122 when the motor pump 111 has previously performed the target pressure. In the process of applying a current to the solenoid valve 114b to open.

As a result, the internal pressure and the external pressure of the cylinder may be parallel to prevent a trip phenomenon. After that, when the internal pressure and the external pressure are maintained in parallel, the adjusting part 123 may adjust the current applied to the solenoid valve 114b. Release to close.

The analysis unit 122 may derive the extraction amount of the beverage extracted from the beverage container through the measurement value of the flow sensor 133 and calculate the cumulative amount of the beverage for a predetermined period of time.

Here, the analysis unit 122 does not proceed to the accumulation of the extraction amount from the initial driving of the motor pump 111, that is, from the trial run to the stop point.

When the driving of the motor pump 111 is not stopped for a predetermined time, the warning unit 124 determines that the air leaks from the flow path 10 to generate an error signal, and then displays a display unit or a communication unit. It can be shown in the user device.

In addition, a warning sound may be generated through the speaker, or a light may be emitted to the user.

In addition, the warning unit 124 generates an extraction prohibition signal when the extraction pressure is less than a predetermined lower limit.

For example, the extraction prohibition signal may be generated when the driving stop state of the motor pump 111 is 80% or less of a target pressure, and when 80% or more, the warning unit 124 generates an extractable signal.

The system 100 further includes a display unit 160, a communication unit 140, and a user device 150.

The display unit 160 is information related to the operation of the system 100, including the measured value of the sensor unit 130, the driving state of the motor pump 111, the total consumption of draft beer, error signal, extraction prohibition signal Can be shown to the user.

The communication unit 140 may be mounted on the printed circuit board in the form of an expansion card, and when mounted, it may be shown on the display unit 160.

Here, the communication unit 140 is connected to the user device 150 through a known wireless method, including Wi-Fi, receives the measurement value of the sensor unit 130, or drive signal of the motor pump 111 or A stop signal and an error signal may be transmitted, and the user may control the system 100 by interworking with a PLC server in an IoT (Internet of Things) method.

The communication unit 140 may include a GPS receiver, through which the position signal of the air pump 110 may be generated in real time, and may be displayed on the display unit 160 to be recognized by the user.

Therefore, the user can more easily perform inventory management of the air pump 110.

The memory 121 may store a position where the customer who purchased the air pump 110 arranges the air pump 110.

Here, the analysis unit 122 extracts the position of the air pump 110 stored in the memory 121, and compares the position with the position signal generated in real time to the position of the air pump 110 in a predetermined range Determine whether it is included.

If it is determined that the position of the air pump 110 is out of a certain range, based on the determination of the analysis unit 122, the warning unit 124 generates a warning signal and the display through the communication unit 140 By showing this to the user in the unit 130, it is possible to lower the possibility of theft and loss of the air pump (110).

The user device 150 may be a known smart device such as a computer (PC), a mobile phone or a smart phone.

For example, the user device 150 may communicate with various digital computers such as laptops, desktops, workstations, personal digital assistants (PDAs), cellular telephones, smart phones, or other suitable computers, as well as IPTV using Internet protocols. It may correspond to a digital device.

The user device 150 includes an application and an input unit.

An application is a kind of software running on an operating system (OS), and refers to a program designed to directly perform a specific function for a user or another application.

In the present invention, the application used in the user's portable terminal, such as a smart phone may be software designed to be applied to a mobile device, the application is a browser-based application that accesses the web, depending on the terminal operating system, the native is produced according to the terminal It can be implemented in the form of a native application, or a hybrid application combining them.

The input unit is an input means for a user to set a target pressure through an application and select a preset mode for each target pressure. For example, a key pad and a touch pad may correspond to the input pressure. Up and down buttons can be included to fine tune the target pressure.

In addition, the input unit may be applied to the display unit 160 including the function of the user device 150.

In addition, the application is shown in the information shown on the display 130, the user can easily determine the state of the system 100 and can manipulate the configuration.

In addition, the user may confirm the failure of the system 100 and attempt to repair the system 100 remotely, or dispatch a repair engineer to promptly proceed.

Hereinafter, the control method of the system described above will be described with reference to FIGS. 1 to 7.

FIG. 7 is a flowchart illustrating a control method of the air pump system for a beverage extraction device shown in FIG. 2.

Referring to FIG. 7, the system 100 performs a target pressure reaching process to extract a beverage from the beverage container.

In the process of reaching the target pressure, first, the air pump 110 is driven (S110), and the sensor unit 130 measures the extraction pressure or the temperature near the air pump.

Thereafter, the controller 120 adjusts the driving of the air pump so that the extraction pressure reaches the target pressure based on the extraction pressure or the temperature (S130).

More specifically, the analysis unit 122 extracts a corresponding target pressure stored in the memory 121 based on the measured value of the sensor unit 130.

Here, the target pressure may be set by the user arbitrarily through the user device 150 or the pressure control valve 114c or by reflecting the capacity difference for each model of the motor pump 111 or the type of beverage.

The target pressure may be changed at any time during the target pressure reaching process.

The adjusting unit 123 transmits a driving signal or a stop signal of the motor pump 111 to the pressure switch 115 so that the extraction pressure reaches the target pressure extracted by the analyzing unit 122, and the pressure switch 115 controls the driving of the motor pump 111 by driving the motor pump 111 or stopping the driving based on this.

Here, the analysis unit 122 determines whether the target pressure has been performed before.

When the analyzer 122 determines that the motor pump 111 has performed the target pressure beforehand, the solenoid before the adjusting unit 123 generates the driving signal of the motor pump 111. A current is applied to the valve 114b to open it.

As a result, the internal pressure and the external pressure of the cylinder may be parallel to prevent a trip phenomenon. After that, when the parallel between the internal pressure and the external pressure is maintained, the adjustment unit 123 may adjust the current applied to the solenoid valve 114b. Release to close.

The control unit 123 transmits a driving signal of the motor pump 111 to the pressure switch 115, and the pressure switch 115 drives the motor pump 111.

Here, when the analysis unit 122 determines that the motor pump 111 has not previously performed the target pressure execution, the adjusting unit 123 omits the opening and closing process of the solenoid valve 114b and the motor. The driving signal of the pump 111 may be generated.

When the motor pump 111 is driven and the driving of the motor pump 111 is not stopped for a predetermined time, the warning unit 124 determines that air is leaking from the flow path 10 to detect an error signal. Create

The warning unit 124 may generate an extraction prohibition signal when the extraction pressure is less than or equal to a predetermined lower limit.

In addition, the system 100 is in the process of checking whether the position of the air pump 110 changes.

In the process of checking whether the position of the air pump 110 changes, first, the communication unit 140 generates a position signal of the air pump 110 through a GPS receiver in real time.

Thereafter, the analysis unit 122 determines whether the position of the air pump 110 is included in a predetermined range based on the position signal (S150).

More specifically, the analysis unit 122 extracts the position of the air pump 110 stored in the memory 121, and compares it with the position signal generated in real time, the air pump 110 in a certain range Determine whether it is included.

Based on the determination of the analyzing unit 122, when it is determined that the position of the air pump 110 is out of a predetermined range, the warning unit 124 generates a warning signal.

In addition, the system 100 is in the process of calculating the total consumption of the beverage.

In the process of calculating the total consumption of the beverage, first, the flow sensor 133 measures the flow rate of air injected into the beverage container.

Thereafter, the analysis unit 122 derives the extraction amount of the beverage based on the flow rate (S170), and calculates the total amount of the beverage by cumulatively calculating the extraction amount of the derived beverage for a predetermined period of time (S180).

Here, the process of checking the positional change of the air pump 110 may be selectively performed at least at any one of the beginning, middle, and end of the process based on the target pressure reaching performance process.

In addition, the process of calculating the total consumption of the beverage may be selectively performed at least at any one of the beginning, the middle, the end of the process based on the process of reaching the target pressure or checking the position change of the air pump 110.

Then, the extraction pressure, the target pressure, the temperature, the driving state and position of the air pump 110, the total consumption of the beverage, warning signal, error signal, extraction prohibition signal to the display unit 130 or the user device 150 At least one of the extractable signals may be shown to the user.

As described above, the air pump system and control method for a beverage extracting apparatus according to the present invention according to an embodiment of the present invention uses the conventional carbon dioxide gas cylinder because it generates the extraction pressure using air instead of carbon dioxide gas through the air pump Can be excluded.

In addition, it is possible to prevent the alteration of the beverage, including draft beer through the above-described effect.

In addition, the driving of the air pump may be automatically adjusted based on the extraction pressure generated by the air pump or the temperature near the air pump.

In addition, by detecting the position of the air pump, inventory management is easy and can reduce the possibility of theft and loss.

In addition, it is possible to check the extraction amount of the beverage in real time, it is possible to easily determine the total consumption of the beverage for a certain period of time.

As described above, the best embodiment has been disclosed in the drawings and the specification. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not used to limit the scope of the present invention as defined in the meaning or claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

100: beverage pump air pump system
110: air pump 120: control unit
130 sensor 140 communication unit
150: user device

Claims (5)

Driving an air pump for injecting air through a flow path connected to a beverage container to generate an extraction pressure for extracting the beverage contained in the beverage container;
Measuring the extraction pressure or a temperature near the air pump; And
And adjusting the driving of the air pump so that the extraction pressure reaches a target pressure based on the measured extraction pressure or temperature.
Driving the air pump,
First compressing the air introduced from the inlet by a first cylinder in which the internal piston reciprocates linearly by the rotational force transmitted from the motor; And
And a second cylinder in which the internal piston reciprocates linearly by the rotational force transmitted from the motor to boost the air compressed in the first cylinder by second compression.
After controlling the driving of the air pump, the solenoid included in the air pump is opened before the re-drive of the motor pump to prevent tripping by making the internal pressure of the cylinder parallel to the external pressure; Air pump system control method for a beverage extraction device further comprising.
The method of claim 1,
Generating a position signal of the air pump; And
Determining whether the position of the air pump is included in a predetermined range based on the position signal;
Air pump system control method for a beverage extraction device further comprising.
The method of claim 1,
Measuring a flow rate of air injected into the beverage;
Deriving an amount of extraction of the beverage based on the flow rate; And
Calculating the total consumption of the beverage by accumulating the extracted amount of the beverage for a predetermined period of time;
Air pump system control method for a beverage extraction device further comprising.
The method of claim 1,
And at least one of the extraction pressure, a target pressure, a temperature, a driving state and a position of the air pump, and a total consumption of the beverage.
An air pump for injecting air through a flow path connected to a beverage container to generate an extraction pressure for extracting the beverage contained in the beverage container;
A sensor unit measuring the extraction pressure or a temperature near the air pump; And
And a controller configured to adjust driving of the air pump so that the extraction pressure reaches a target pressure based on the measured extraction pressure or temperature.
The air pump,
A motor pump composed of a pair of cylinders having a piston installed therein, and a motor driving the piston; And
And a solenoid opened before re-driving of the motor pump to prevent tripping by parallelizing an internal pressure of the cylinder with an external pressure.
The piston is
Receives the rotational force of the motor to reciprocate linearly move the inside of the cylinder to compress air to discharge to the flow path,
The cylinder,
A first cylinder through which air is introduced from the inlet and performing a first compression process; And
And a second cylinder configured to pressurize the air compressed by the first cylinder to increase the pressure by the second cylinder. 2.

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